JPWO2008120502A1 - Antenna and wireless communication device - Google Patents

Abstract

A feeding radiation electrode (21) and a non-feeding radiation electrode (22) are provided from the front side surface to the top surface of the dielectric substrate (20), and the feeding radiation electrode (21) has a slit (23 extending inward from the feeding end (25). ), A slit (24) extending inward from the ground end (26) is formed in the parasitic radiation electrode (22). Further, a branch electrode (27) is formed on the non-feed radiation electrode (22) so as to extend toward the feed radiation electrode (21). With this configuration, gain is gained in two frequency bands using the double resonance of the fundamental resonance and the harmonic resonance of the feed radiation electrode and the non-feed radiation electrode, and the return loss due to the coupling of the harmonic resonances. Good characteristics.

Description

  The present invention relates to an antenna used in a wireless communication device such as a mobile communication device and a wireless communication device including the antenna.

  Patent Documents 1 and 2 are disclosed as antennas used in a plurality of frequency bands in a wireless communication device such as a terminal device (mobile phone) of a mobile phone system. FIG. 1 is a perspective view of an antenna disclosed in Patent Document 1. FIG. In FIG. 1, a radiation electrode 12 and parasitic electrodes 13 and 14 are formed on the upper surface of a dielectric substrate 11. A ground electrode 15 is formed on the entire lower surface of the dielectric substrate 11 so as not to contact the excitation conductor 19. Further, grounding conductors 16, 17, 18 for grounding the radiation electrode 12 and the parasitic electrodes 13, 14 are formed on the side surfaces of the dielectric substrate 11, respectively.

  In this way, a wideband antenna is realized by forming a radiation electrode and a plurality of parasitic electrodes having resonance frequencies close to the radiation electrode in the same plane and combining a plurality of resonances.

Patent Document 2 shows that an antenna having gains in two frequency bands is configured by using double resonances of fundamental resonances and harmonic resonances of a feeding electrode and a parasitic electrode. . Specifically, by forming spiral slits in each of the feeding electrode and the non-feeding electrode, the resonance frequency of the harmonic resonance (higher order mode) can be reduced without substantially changing the frequency of the fundamental resonance (fundamental mode). The desired frequency is set.
JP-A-11-127014 JP 2003-8326 A

  However, as shown in Patent Document 2, although it is possible to control the resonance frequency of the harmonic by providing slits in each of the feeding electrode and the non-feeding electrode, the resonance frequency of the fundamental wave and the resonance of the harmonic wave are possible. Depending on the combination with the frequency, it often occurs that the matching at the resonance frequency of the harmonic cannot be obtained, and the optimum return loss may not be obtained. That is, when considering the capacitive coupling between the feeding electrode and the parasitic electrode, as the length of the slit formed in each of the feeding electrode and the parasitic electrode increases, the inductance increases and the capacitance decreases. The amount of coupling between harmonic resonances between the feeding electrode and the non-feeding electrode becomes weak, and a return loss at the harmonic resonance frequency increases, resulting in a problem that a desired gain cannot be obtained.

  Therefore, an object of the present invention is to provide a harmonic resonance between antennas having gains in two frequency bands by utilizing the double resonance between the fundamental resonance and the harmonic resonance between the feed radiation electrode and the parasitic radiation electrode. An object of the present invention is to provide an antenna having a good return loss characteristic due to coupling and a radio communication apparatus including the antenna.

In order to solve the above problems, the present invention is configured as follows.
(1) Almost ¼ wavelength feed radiation electrode with one end serving as a feed point and the other end as an open end, a ground end as one end, and the other end as an open end on a dielectric or dielectric and magnetic substrate. In the antenna, which is provided with a parasitic radiation electrode as an end, and uses multiple resonances of fundamental resonance and harmonic resonance between the feeding radiation electrode and the parasitic radiation electrode, the feeding radiation electrode and the parasitic radiation electrode And a branch electrode extending from the non-feeding radiation electrode to the feeding radiation electrode side.

  (2) The feeding radiation electrode is formed with a spiral or spiral partial slit in an electrode extending in a plane to determine an electrical length from the feeding point to the open end of the feeding radiation electrode, and the parasitic radiation The electrode may have an electrical length from the ground end to the open end of the non-feeding radiation electrode by forming a spiral or spiral partial slit in the electrode spreading in a planar shape.

  (3) Further, the wireless communication device of the present invention includes the antenna, and includes a wireless communication circuit that feeds power to the feeding radiation electrode.

  According to the present invention, an electrode having a length shorter than that of the parasitic radiation electrode is formed so as to extend from the parasitic radiation electrode side to the feeder radiation electrode side. The strength of coupling between the harmonic resonances of the non-feeding radiation electrode and the feeding radiation electrode is increased, and the return loss in the frequency band due to the double resonance between the harmonic resonances can be reduced.

  In addition, by forming a spiral slit in the electrode extending in a planar shape for each of the feeding radiation electrode and the non-feeding radiation electrode, the harmonic resonance frequency is set to a desired frequency while keeping the fundamental resonance frequency substantially constant. be able to. By providing the branch electrode even under the condition that the coupling amount of the harmonic resonance between the feeding radiation electrode and the non-feeding radiation electrode is reduced by increasing the length of the slit to lower the harmonic resonance frequency. Since a desired return loss characteristic at the harmonic resonance frequency can be obtained, the degree of freedom of the combination of the fundamental resonance frequency and the harmonic resonance frequency is increased.

It is a figure which shows the structure of the antenna shown by patent document 1. FIG. It is each perspective view of the antenna which concerns on 1st Embodiment, and the antenna as a comparative example. It is a figure which shows the frequency characteristic of the return loss of two antennas shown in FIG. It is a top view of the antenna which concerns on 2nd Embodiment.

Explanation of symbols

20-Substrate 21, 31-Feed radiation electrode 22, 32-Non-feed radiation electrode 23, 24, 33, 34-Slit 25, 35-Feed end 26, 36-Ground end 27, 37-Branch electrode 30-Substrate 40- Feeding means 101, 102-antenna

<< First Embodiment >>
An antenna and a wireless communication apparatus according to the first embodiment will be described with reference to FIGS.
2A is a perspective view of an antenna according to the first embodiment, and FIG. 2B is a perspective view of an antenna as a comparative example.

  As shown in FIG. 2 (A), the antenna 101 according to the first embodiment includes a feeding radiation electrode 21 and a parasitic radiation electrode that spread in a planar shape from the front side surface to the top surface of the rectangular parallelepiped dielectric substrate 20. 22 is provided. In this example, the dielectric substrate 20 is a non-magnetic dielectric material, but may be a dielectric material and a magnetic material.

  The feeding radiation electrode 21 and the non-feeding radiation electrode 22 are formed with slits 23 and 24 each having a spiral shape or a spiral shape. A slit 23 formed in the feeding radiation electrode 21 extends inward from a feeding end (corresponding to a feeding point according to the present invention) 25, and a slit 24 provided in the non-feeding radiation electrode 22 extends inward from a ground end 26. ing. With this configuration, a feeding radiation electrode 21 having one end as a feeding point and the other end as an open end and having a fundamental wave of approximately ¼ wavelength, and a parasitic radiation electrode having one end as a ground end and the other end as an open end 22 is formed.

  As described above, the slits 23 and 24 are provided in the feeding radiation electrode 21 and the non-feeding radiation electrode 22 spreading in a plane shape, thereby determining the electrical length from the feeding end to the open end of the feeding radiation electrode, and from the ground end. Determine the electrical length to the open end of the parasitic radiation electrode. With this structure, it is possible to set the resonance frequency of the harmonic resonance (higher order mode) to a desired frequency while keeping the frequency of the fundamental resonance (fundamental mode) at the desired frequency. That is, the fundamental frequency and the harmonic frequency can be set independently of each other. The principle is as disclosed in Patent Document 2.

  A branch electrode 27 is formed from the non-feeding radiation electrode 22 to the feeding radiation electrode 21 side. In this example, the parasitic radiation electrode 22 is formed so as to extend away from the side near the ground end 26, and is arranged substantially parallel to the edge of the radiation radiation electrode 21. Since the branch electrode 27 is for increasing capacitive coupling between harmonic resonances between the parasitic radiation electrode 22 and the parasitic radiation electrode 21, the length of the parasitic radiation electrode 22 (the length along the slit). It is shorter.

  FIG. 2B shows an antenna having a structure in which the branch electrode 27 shown in FIG. 2A is not formed as a comparative example.

  FIG. 3 shows the frequency characteristics of the return loss of the two antennas shown in FIGS. FIG. 3A shows the characteristics of the antenna 101 according to the first embodiment shown in FIG. 2A, and FIG. 3B shows the characteristics of the antenna as a comparative example shown in FIG.

  In FIG. 3, F <b> 1 is a fundamental resonance frequency by the feed radiation electrode 21, and F <b> 2 is a second harmonic resonance frequency by the feed radiation electrode 21. F1 is a fundamental resonance frequency by the parasitic radiation electrode 22, and f2 is a second harmonic resonance frequency by the parasitic radiation electrode 22.

  The one-dot chain line is the frequency characteristic of the return loss due to the feeding radiation electrode 21, and the dashed curve is the frequency characteristic of the return loss due to the parasitic radiation electrode 22. Further, the solid curve is a characteristic due to the double resonance of the fundamental resonance and the harmonic resonance of the feed radiation electrode 21 and the non-feed radiation electrode 22.

  In FIG. 3, the frequency band of f1-F1 corresponds to CDMA800 (843 to 890 MHz), and the frequency band of f2-F2 corresponds to CDMA2000 (2110 to 2130 MHz). That is, this antenna acts as a dual band antenna for CDMA800 / 2000.

  As shown in FIG. 3B, an antenna in which a feeding radiation electrode 21 having a slit 23 and a parasitic radiation electrode 22 having a slit 24 are simply arranged at a predetermined interval as shown in FIG. The coupling between the two harmonic resonances is weak, and the return loss at the frequencies f2 to F2 is not sufficiently reduced. On the other hand, in the first embodiment shown in FIG. 2A, the amount of coupling between the harmonic resonances is sufficiently ensured, and the double resonance can be used.

<< Second Embodiment >>
FIG. 4 is a plan view of the antenna 102 according to the second embodiment.
In the first embodiment, various electrodes are formed on a rectangular parallelepiped dielectric base. In the second embodiment, the electrodes are formed on a substrate. In FIG. 4, a feeding radiation electrode 31 and a parasitic radiation electrode 32 are provided on the upper surface of the substrate 30 so as to spread in a planar shape. The feeding radiation electrode 31 and the non-feeding radiation electrode 32 are formed with spiral slits 33 and 34, respectively. A slit 33 formed in the feed radiation electrode 31 extends inward from the feed end 35, and a slit 34 provided in the non-feed radiation electrode 32 extends inward from the ground end 36.

  A branch electrode 37 is formed from the non-feeding radiation electrode 32 to the feeding radiation electrode 31 side. In this example, the parasitic radiation electrode 32 is formed so as to extend in a direction far from the side near the ground end 36 and is arranged substantially parallel to the edge of the feeder radiation electrode 31.

  By providing the branch electrode 37 in this manner, the coupling capacitance between the feeding radiation electrode 31 and the parasitic radiation electrode 32 is increased, and a sufficient amount of coupling between harmonic resonances is ensured, and the double resonance is utilized. Can do.

<< Third Embodiment >>
A wireless communication device such as a cellular phone is configured as follows using the antenna shown in the first and second embodiments.
For example, when the antenna 101 shown in FIG. 2 is used, a wireless communication circuit including the power feeding means 40 is provided on a mounting substrate, a non-ground region is provided at an end of the mounting substrate, and the antenna 101 is provided in the non-ground region. Surface mount. As a result, a mobile phone compatible with both CDMA800 / 2000 can be configured.

  When the antenna 102 shown in FIG. 4 is used, the antenna 102 is surface-mounted on a non-ground region of the mounting substrate, or each pattern of the antenna 102 is directly formed on the mounting substrate.

Claims (3)

An approximately 1/4 wavelength feed radiation electrode with one end as a feed point and the other end as an open end, and one end as a ground end and the other end as an open end on a dielectric or dielectric and magnetic substrate. In an antenna provided with a parasitic radiation electrode, and utilizing the double resonance of each fundamental wave resonance and harmonic resonance between the feeding radiation electrode and the parasitic radiation electrode,
The antenna is characterized in that the feeding radiation electrode and the parasitic radiation electrode are arranged at a predetermined interval, and a branch electrode is extended from the parasitic radiation electrode to the feeding radiation electrode side.   The feeding radiation electrode has a spiral or spiral partial shape slit formed in an electrode extending in a planar shape to determine the electrical length from the feeding point to the open end of the feeding radiation electrode, the parasitic radiation electrode is The antenna according to claim 1, wherein a spiral or spiral partial slit is formed in a planar electrode to determine an electrical length from the ground end to the open end of the parasitic radiation electrode.   A wireless communication apparatus comprising the antenna according to claim 1 or 2 and further including a wireless communication circuit that supplies power to the feeding point.

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